与原子力显微镜相关的高光谱暗场光学显微镜用于分析单个等离子纳米粒子:教程

Claire Abadie, Mingyang Liu, Yoann Prado, Olivier Pluchery
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摘要

人们正在积极研究等离子纳米结构的光学特性,并将其广泛应用于纳米光子学、生物传感、光催化、热载流子物理学和先进的癌症疗法。局部表面等离子体共振(LSPR)可在金或银纳米粒子或更复杂的纳米结构中激发,并产生各种独特的光学特性。能够定位单个等离子纳米粒子并同时测量其光谱往往至关重要。这就是所谓的高光谱显微技术。在本教程中,我们将描述并仔细讲解如何使用配备暗视野物镜和光学光谱仪的光学显微镜来实现这一目标。我们记录了直径分别为 90、70、50 和 25 纳米的球形金纳米粒子的图像和散射光谱。我们将它们与用米氏公式预测的散射光谱(分别在 553、541、535 和 534 纳米处测得 LSPR 峰值)进行了比较。光学图像受到衍射的限制,我们将在阿贝方程的框架内对此进行讨论。我们还介绍了一种将光学图像与样品的原子力显微镜图像轻松关联起来的策略。这样,我们就能将纳米粒子的形态与它们的光学图像、颜色和光谱精确地联系起来。我们还讨论了非球形纳米结构(即纳米粒子的二聚体)的情况。这种方法可以实现相对低成本的设置和高效的表征方法,对希望向学生介绍等离子体学广泛主题的教师很有帮助。这也将有助于实验室寻找一种经济实惠的方法来研究单个纳米结构的等离子特性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Hyperspectral dark-field optical microscopy correlated to atomic force microscopy for the analysis of single plasmonic nanoparticles: tutorial
Plasmonic nanostructures are actively investigated for their optical properties and for a wide range of applications in nanophotonics, biosensing, photocatalysis, hot carrier physics, and advanced cancer therapies. The localized surface plasmon resonance (LSPR) can be excited in gold or silver nanoparticles or in more complex nanostructures and gives rise to a wide range of unique optical properties. It is often critical to be able to localize individual plasmonic nanoparticles and simultaneously measure their spectrum. This is known as hyperspectral microscopy. In this tutorial, we describe and carefully explain how to achieve this goal with an optical microscope equipped with a dark-field objective and an optical spectrometer. The images and the scattering spectra of spherical gold nanoparticles with diameters of 90, 70, 50, and 25 nm are recorded. We compare them with the scattering spectra predicted with the Mie formula (LSPR peaks measured at 553, 541, 535, and 534 nm, respectively). The optical images are limited by the diffraction, and this is discussed in the framework of the Abbe equation. We also describe a strategy to easily correlate the optical images with atomic force microscope images of the samples. This allows us to precisely relate the morphology of the nanoparticles with their optical images, their color, and their optical spectrum. The case of non-spherical nanostructures, namely, dimers of nanoparticles, is also discussed. This approach allows a relatively low-cost setup and efficient characterization method that will be helpful for teachers who want to introduce their students to the wide topics of plasmonics. This will also be useful for labs seeking an affordable method to investigate the plasmonic properties of single nanostructures.
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